Sheng Hong

Rational Design of Multifunctional Magnetic Mesoporous Silica Nanoparticle for Tumor-Targeted Magnetic Resonance Imaging and Precise Therapy

In this paper, a multifunctional theranostic magnetic mesoporous silica nanoparticle (MMSN) with magnetic core was developed for magnetic-enhanced tumor-targeted MR imaging and precise therapy. The gatekeeper β-cyclodextrin (β-CD) was immobilized on the surface of mesoporous silica shell via platinum(IV) prodrug linking for reduction-triggered intracellular drug release. Then Arg-Gly-Asp (RGD) peptide ligand was further introduced onto the gatekeeper β-CD via host-guest interaction for cancer targeting purpose. After active-targeting endocytosis by cancer cells, platinum(IV) prodrug in MMSNs would be restored to active platinum(II) drug in response to the innative reducing microenvironment in cancer cells, resulting in the detachment of β-CD gatekeeper and thus simultaneously triggering the in situ release of anticancer drug doxorubicin (DOX) entrapped in the MMSNs to kill cancer cells. It was found that with the aid of an external magnetic field, drug loaded MMSNs showed high contrast in MR imaging inxa0vivo and exhibited magnetically enhanced accumulation in the cancer site, leading to significant inhibition of cancer growth with minimal side effects. This multifunctional MMSN will find great potential as a theranostic nanoplatform for cancer treatment.

Overcoming the Heat Endurance of Tumor Cells by Interfering with the Anaerobic Glycolysis Metabolism for Improved Photothermal Therapy

In this study, we developed a general method to decorate plasmonic gold nanorods (GNRs) with a CD44-targeting functional polymer, containing a hyaluronic acid (HA)-targeting moiety and a small molecule Glut1 inhibitor of diclofenac (DC), to obtain GNR/HA-DC. This nanosystem exhibited the superiority of selectively sensitizing tumor cells for photothermal therapy (PTT) by inhibiting anaerobic glycolysis. Upon specifically targeting CD44, sequentially time-dependent DC release could be achieved by the trigger of hyaluronidase (HAase), which abundantly existed in tumor tissues. The released DC depleted the Glut1 level in tumor cells and induced a cascade effect on cellular metabolism by inhibiting glucose uptake, blocking glycolysis, decreasing ATP levels, hampering heat shock protein (HSP) expression, and ultimately leaving malignant cells out from the protection of HSPs to stress (e.g., heat), and then tumor cells were more easy to kill. Owing to the sensitization effect of GNR/HA-DC, CD44 overexpressed tumor cells could be significantly damaged by PTT with an enhanced therapeutic efficiency in vitro and in vivo.

Rational Design of Multifunctional Gold Nanoparticles via Host–Guest Interaction for Cancer-Targeted Therapy

A versatile gold nanoparticle-based multifunctional nanocomposite AuNP@CD-AD-DOX/RGD was constructed flexibly via host-guest interaction for targeted cancer chemotherapy. The pH-sensitive anticancer prodrug AD-Hyd-DOX and the cancer-targeted peptide AD-PEG8-GRGDS were modified on the surface of AuNP@CD simultaneously, which endowed the resultant nanocomposite with the capability to selectively eliminate cancer cells. In vitro studies indicated that the AuNP@CD-AD-DOX/RGD nanocomposite was preferentially uptaken by cancer cells via receptor-mediated endocytosis. Subsequently, anticancer drug DOX was released rapidly upon the intracellular trigger of the acid microenvirenment of endo/lysosomes, inducing apoptosis in cancer cells. As the ideal drug nanocarrier, the multifunctional gold nanoparticles with the active targeting and controllable intracellular release ability hold the great potential in cancer therapy.

Programmed Nanococktail for Intracellular Cascade Reaction Regulating Self-Synergistic Tumor Targeting Therapy.

In this work, a ZnO based nanococktail with programmed functions is designed and synthesized for self-synergistic tumor targeting therapy. The nanococktail can actively target tumors via specific interaction of hyaluronic acid (HA) with CD44 receptors and respond to HAase-rich tumor microenvironment to induce intracellular cascade reaction for controlled therapy. The exposed cell-penetrating peptide (R8) potentiates the cellular uptake of therapeutic nanoparticles into targeted tumor cells. Then ZnO cocktail will readily degrade in acidic endo/lysosomes and induce the production of desired reactive oxygen species (ROS) in situ. The destructive ROS not only leads to serious cell damage but also triggers the on-demand drug release for precise chemotherapy, thus achieving enhanced antitumor efficiency synergistically. After tail vein injection of ZnO cocktail, a favorable tumor apoptosis rate (71.2 ± 8.2%) is detected, which is significantly superior to that of free drug, doxorubicin (12.9 ± 5.2%). Both in vitro and in vivo studies demonstrate that the tailor-made ZnO cocktail with favorable biocompatibility, promising tumor specificity, and self-synergistically therapeutic capacity opens new avenues for cancer therapy.

Targeting epithelial-mesenchymal transition: Metal organic network nano-complexes for preventing tumor metastasis.

Tumor metastasis is the leading cause of death in cancer patients, and epithelial-mesenchymal transition (EMT) is an essential step in tumor metastasis. Unfortunately, during the chemotherapy, EMT could be induced under the selective pressure of clinical cytotoxic drugs. Here, to solve this problem, we have synthesized multi-functional epigallocatechin gallate/iron nano-complexes (EIN) as a versatile coating material to improve conventional therapies. Inxa0vitro studies showed that this strategy could eliminate EMT-type cancer cells. Mechanism studies also revealed that EIN was able to down-regulate the downstream expression of metastasis-associated factors, decrease the migration ability of cancer cells and prevent cancer cells from gaining drug resistance. Inxa0vivo investigation revealed that EIN had superior ability to enhance the therapeutic effect of conventional nanomedicines and inhibit the EMT process. Our study indicates the promising use of EIN to make up for the deficiencies of chemotherapy may provide insights into systematic cancer therapy to overcome tumor metastasis and drug resistance.

A metal–semiconductor nanocomposite as an efficient oxygen-independent photosensitizer for photodynamic tumor therapy

Photodynamic therapy (PDT) is regarded as one of the most promising cancer treatments, and oxygen-independent photosensitizers have been intensively explored for advancing the development of PDT. Here, we reported on a superior hybrid nanocomposite (HNC) consisting of a metal (Au deposition) and a semiconductor (CdSe-seeded/CdS nanorods) as a photosensitizer. Under visible light, the photogenerated holes were three-dimensionally confined to the CdSe quantum dots and the delocalized electrons were transferred to the Au tips, which provided hydrogen and oxygen evolution sites for water splitting to generate reactive oxygen species (ROS) with no need for oxygen participation. Compared with semiconductors without deposited metal (i.e. raw CdSe-seeded/CdS nanorods (NRs)) under a normoxic or hypoxic environment, the HNCs exhibited substantially enhanced light-triggered ROS generation in vitro. After being modified with an Arg-Gly-Asp (RGD) peptide sequence, the nanocomposite was deemed as a tumor-targeting, long-lived and oxygen-independent photosensitizer with promoted PDT efficiency for in vivo anti-tumor therapy. This oxygen-independent nanocomposite successfully overcame the hypoxia-related PDT resistance by water splitting, which opened a window to develop conventional semiconductors as photosensitizers for effective PDT.

Hierarchical Micro‐/Nanostructures from Human Hair for Biomedical Applications

With the prominent progress of biomedical engineering, materials with high biocompatibility and versatile functions are urgently needed. So far, hierarchical structures in nature have shed some light on the design of high performance materials both in concept and implementation. Inspired by these, the hierarchical micro-/nanostructures of human hair are explored and human hair is further broken into hierarchical microparticles (HMP) and hierarchical nanoparticles (HNP) with top-down procedures. Compared with commercialized carriers, such as liposomes or albumin nanoparticles, the obtained particles exhibit high hemocompatibility and negligible immunogenicity. Furthermore, these materials also display attentional abilities in the aspects of light absorption and free radical scavenging. It is found that HMP and HNP can prevent skin from UV-induced damage and relieve symptoms of cataract in vitro. Besides, both HMP and HNP show satisfactory photothermal conversion ability. By using microcomputed tomography and intravital fluorescence microscopy, it is found that warfarin-loaded HMP can rescue mice from vein thrombosis. In another aspect, HNP modified with tumor targeted aptamers exhibit dramatic antineoplastic effect, and suppress 96.8% of tumor growth in vivo. Thus, the multifaceted materials described here might provide a new tool for addressing biomedical challenges.

Tumor Targeting: Programmed Nanococktail for Intracellular Cascade Reaction Regulating Self‐Synergistic Tumor Targeting Therapy (Small 6/2016)

An improved antitumor therapy can be achieved by rationally designing an intelligent nanomedicine with programmed functions to specifically eliminate tumors while leaving healthy tissues untouched. On page 733, X.-Z. Zhang and co-workers demonstrate a tailor-made ZnO-based nanococktail with a stealth capacity to trigger an intracellular cascade reaction, releasing drugs on-demand for tumor-specific therapy.

A Universal Approach to Render Nanomedicine with Biological Identity Derived from Cell Membranes

Biomimetic nanoengineering built through integrating the specific cell membrane with artificially synthetic nanomedicines represents one of the most promising directions for the actualization of personalized therapy. For addressing the technical hurdle against the development of this biomimetic technology, the present report describes the in-depth exploration and optimization over each critical preparation step, including establishment of a nanoparticle-stabilized dispersion system, cargo loading, membrane coating, and product isolation. Magnetic iron oxide nanoparticles loaded with DOX is used as a typical model for the coating with cancer cell membranes, providing compact DNP@CCCM nanostructure well-characterized by various techniques. Furthermore, the feasibility of this optimized approach in constructing biomimetic membrane-coated nanomedicines has been validated on the basis of the remarkably improved biofunctions, such as the targetability, magnetic property, hemolysis risk, macrophage evasion, in vitro cytotoxicity, in vivo circulation duration, and in vivo principal component analysis postinjection. We hope this study regarding technique optimization will prompt the advancement of biomembrane-camouflaged nanoparticles as a newly emerging biomimetic technology.